English

Geometric pathway to scalable quantum sensing

Quantum Physics 2020-11-11 v5

Abstract

Entangled resources enable quantum sensing that achieves Heisenberg scaling, a quadratic improvement on the standard quantum limit, but preparing large scale entangled states is challenging in the presence of decoherence. We present a quantum control strategy using highly nonlinear geometric phase gates for preparing entangled states on spin ensembles which can be used for practical precision metrology. The method uses a dispersive coupling of NN spins to a common bosonic mode and does not require addressability, special detunings, or interactions between the spins. Using a control sequence that executes Grover's algorithm on a subspace of permutationally symmetric states, a target entangled resource state can be prepared using O(N5/4)O(N^{5/4}) geometric phase gates. The geometrically closed path of the control operations ensures the gates are insensitive to the initial state of the mode and the sequence has built-in dynamical decoupling providing resilience to dephasing errors.

Keywords

Cite

@article{arxiv.1908.01120,
  title  = {Geometric pathway to scalable quantum sensing},
  author = {Mattias T. Johnsson and Nabomita Roy Mukty and Daniel Burgarth and Thomas Volz and Gavin K. Brennen},
  journal= {arXiv preprint arXiv:1908.01120},
  year   = {2020}
}

Comments

5 pages + 6 pages supplementary, 3 + 1 figures

R2 v1 2026-06-23T10:38:46.989Z